US5381344A - Apparatus and method for obtaining a list of numbers of wafers for integrated circuit testing - Google Patents
Apparatus and method for obtaining a list of numbers of wafers for integrated circuit testing Download PDFInfo
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- US5381344A US5381344A US07/863,257 US86325792A US5381344A US 5381344 A US5381344 A US 5381344A US 86325792 A US86325792 A US 86325792A US 5381344 A US5381344 A US 5381344A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L22/00—Testing or measuring during manufacture or treatment; Reliability measurements, i.e. testing of parts without further processing to modify the parts as such; Structural arrangements therefor
- H01L22/20—Sequence of activities consisting of a plurality of measurements, corrections, marking or sorting steps
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
- G01R31/28—Testing of electronic circuits, e.g. by signal tracer
- G01R31/2832—Specific tests of electronic circuits not provided for elsewhere
- G01R31/2834—Automated test systems [ATE]; using microprocessors or computers
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R31/00—Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
- G01R31/28—Testing of electronic circuits, e.g. by signal tracer
- G01R31/317—Testing of digital circuits
- G01R31/3181—Functional testing
- G01R31/3185—Reconfiguring for testing, e.g. LSSD, partitioning
- G01R31/318516—Test of programmable logic devices [PLDs]
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L23/00—Details of semiconductor or other solid state devices
- H01L23/544—Marks applied to semiconductor devices or parts, e.g. registration marks, alignment structures, wafer maps
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2924/00—Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
- H01L2924/0001—Technical content checked by a classifier
- H01L2924/0002—Not covered by any one of groups H01L24/00, H01L24/00 and H01L2224/00
Definitions
- the present invention relates generally to an apparatus and method for entering data into an integrated circuit (IC) tester, and more particularly, to an apparatus and method for obtaining a list of numbers of wafers for integrated circuit testing.
- IC integrated circuit
- each wafer is numbered so that test results can be matched with the proper wafers. These numbers must be accurately entered into the test program.
- a first technique for wafer number entry is to manually type a list of numbers through an ASCII-based on terminal.
- the user manipulates numbers on the list via keyboard commands.
- This approach requires much typing and is therefore tedious and prone to error.
- it does not provide an intuitive representation of the cassette (which holds wafers being tested).
- an error generally requires the user to begin typing the list over again.
- this approach does not enable the user to specify that certain wafers in the cassette are not to be tested.
- a third approach to wafer number entry is to read the wafer numbers with a wafer reader, save the results to a file, and transmit the contents of the file to the test program.
- This approach still does not provide for skipping wafers in the cassette, and still is not an intuitive representation of the cassette. Furthermore, it requires the user to make the file created by the wafer reader accessible to the test program. Therefore, what is needed is a way to enter wafer numbers into the test program which requires little typing, presents the list as an intuitive representation of the cassette, provides extensive editing tools, and provides for skipping wafers in the cassette.
- the invention is a method for enabling a user to enter wafer numbers into a computer-based integrated circuit production test system.
- the method comprises the steps of: (a) prompting the user for the wafer numbers; (b) displaying the wafer numbers in a graphical representation of a wafer cassette; (c) enabling the user to edit the wafer numbers on the graphical representation; and (d) transmitting the wafer numbers to the computer-based IC production test system.
- FIG. 1 shows a block diagram of the invention in the environment in which it operates
- FIG. 2 is a high level flowchart of the method of the invention
- FIGS. 3A, 3B, 3C and 3D show screen displays of a flag interface module 118 of FIG. 1;
- FIG. 4 shows a block diagram of the flag interface module 118 of FIG. 1;
- FIGS. 5A and 5B show a flowchart of a step 416 of FIG. 4 of updating the flag interface menus
- FIGS. 6A and 6B show a flowchart for the method of a step 420 of FIG. 4 of processing an X event
- FIG. 7 shows a flowchart of the method of a step 638 of FIG. 6B of changing the user mode
- FIG. 8 shows a menu displayed by a top level interface 114 of FIG. 1;
- FIG. 9 shows a high level flowchart of the method of the top level interface in of FIG. 1;
- FIGS. 10A and 10B show a flowchart of the method of a step 914 of FIG. 9 of processing an X event
- FIG. 11 shows a flowchart for the method for a step 1020 of FIG. 10A of selecting data on the top level menu of FIG. 8;
- FIG. 12 shows a flowchart of the method for a step 1110 of FIG. 11 of validating a lot number
- FIG. 13 shows a flowchart for the method of a step 1112 of FIG. 11 of validating a device type
- FIG. 14 shows a flowchart for the method of a step 1114 of FIG. 11 of validating a device suffix
- FIG. 15 shows a flowchart of the method of performing a prodtest of FIG. 1;
- FIG. 16 shows a block diagram of a prober controller 146 of FIG. 1;
- FIG. 17A shows a block diagram of a handler controller 150 of FIG. 1;
- FIG. 17B shows a block diagram of a package controller 154 of FIG. 1;
- FIGS. 18A and 18B show a flowchart of the method of operation of the prober controller 146 of FIG. 16;
- FIG. 19 shows a flowchart of the method of operation of a pause module 1722 of FIG. 16;
- FIGS. 20A and 20B show a flowchart of the method of operation of the wafer map display 164 of FIG. 1;
- FIGS. 21A and 21B show a flowchart of the method of operation of the handler controller 150 of FIG. 17A;
- FIG. 22 shows a flowchart of the method of operation of the package controller 154 of FIG. 17B;
- FIGS. 23A, 23B and 23C show a flowchart of the method of operation of a wafer entry interface 1716 of the prober controller of FIG. 16;
- FIG. 24 shows a wafer entry menu displayed by the wafer entry interface 1716 of FIG. 16;
- FIG. 25 shows a testflow list of a testflow module 158 of FIG. 1;
- FIGS. 26A, 26B and 26C show a flowchart which illustrates the method of operation of the testflow module 158 of FIG. 1;
- FIGS. 27A and 27B show a flowchart of the method of operation of a binning module 160 of FIG. 1;
- FIG. 28 shows a wafer map displayed by the wafer map display 164 of FIG. 1;
- FIG. 29 shows a block diagram of the structure of the wafer map display 164 of FIG. 1;
- FIG. 30 shows a method of a prodconf 144 of FIG. 1;
- FIG. 31 shows a block diagram of the binning module 160 of FIG. 1.
- FIG. 1 shows a block diagram of the environment in which a test shell, called a prodshell 110, of the present invention operates.
- the prodshell 110 receives input from a user 113 and communicates with a shared memory 112.
- the prodshell 110 comprises a top-level interface 114 for obtaining initial information needed for testing a device.
- the device is shown as an integrated circuit (IC) device, such as a die on a wafer or a package part.
- the prodshell 110 invokes a flag interface 118 to enable the user 113 to change the value of flags in the shared memory 112 which control the operation of the prodshell 110, including which tests are performed, the level of result reporting desired, the location or locations to which test results are sent and the appearance of the user 113 interfaces.
- IC integrated circuit
- the prodshell 110 transfers control to a process which executes a prodtest 120.
- the prodtest 120 communicates with a package handler 122 or wafer prober 124 and a tester 126. (During a single execution, the prodtest 120 communicates with either the package handler 122 or the wafer prober 124.)
- the prodtest 120 commands the package handler 122 or wafer prober 124 to position the device appropriately for the next test.
- the prodtest 120 then invokes the tester 126 to carry out that test.
- the prodtest 120 receives information from a configuration file 128 and from data files 130.
- the data files 130 could comprise, for example, a wafer download file containing information such as the geometry of a wafer, the chuck temperature and the alignment target, a calibration file, a pin attributes file, and chip pin, levels and timing files.
- the prodtest 120 transmits test results to the user 113 via a report file 132, a printer 134, and/or a display device 136, as specified by the user 113.
- FIG. 2 is a flowchart which illustrates the method of the present invention.
- the prodshell 110 invokes the flag interface 118.
- the flag interface displays a graphical interface for facilitating the changing of the flag values in the shared memory 112.
- the flag interface is described in detail below in the section entitled "Flag Interface.”
- the prodshell 110 transfers control to the top-level interface 114.
- the top level interface 114 displays a graphical interface to query the user 113 for initial information needed to test the device. Specifically, the interface 114 queries the user for a lot number identifying the lot (group) of wafers (wafer group) to be tested, an identifier of the person performing the test, a grouping for the type of test to be performed (either production, QA or engineering), the temperature at which the device will be tested, the type of the device, and the test to be performed (either wafer autoprobe, wafer manual, package handler 122 or package manual), and an identifier of the type of part being tested and of the configuration file 128.
- the top-level interface 114 is described in greater detail below, in the section entitled "Top-level interface.”
- the prodshell 110 determines whether user code exists.
- the user code consists of one or more routines written by the user 113 to customize the testshell to a particular test site. If the user code exists, then in a step 216, the prodshell 110 executes a compiler to link the prodtest 120 with the user code. Linking the prodtest 120 and the user code enables the latter to easily communicate with other prodtest 120 modules and variables.
- the prodshell 110 transfers control to a process which executes the prodtest 120. After executing the prodtest 120, control of flow of the prodshell 110 returns to the step 210.
- the method of the prodtest 120 is described below in the section entitled "Prodtest.”
- the configuration file 128 is a high level test language which allows the user 113 to specify the nature of the testing, binning, and reporting desired for the particular IC device 116 under test.
- the structure of the configuration file 128 is as follows (lines beginning with "--" are comments):
- a test specification may contain:
- Test suites are the basic units of a test sequence. All the -- characteristics previously defined are brought together in a -- test suite.
- test suite specification contains any or all of:
- testflow section sets out how test suites are to be executed
- the binning section specifies how the results of test suites are to be -- used to grade parts.
- Testflow and binning expressions are in this form:
- the prodshell 110 supports a number of flags which enable the user 113 to change its behavior while it is running. There are essentially three categories of flags. First, system flags control the operation of the prodshell 110 in general. For example, they control the verbosity of output and where the output is sent. Second, user flags are used by the user code and by the user -- func routine (described below). Third, test suite flags control the test flow and the type of output sent to the report window, the printer 134, and the report file 132.
- the purposes of the flag interface 118 are to (1) allocate and initialize the system flags, and (2) enable the user 113 to change the value of any flag.
- the flag interface 118 displays a flag interface 118 main menu, and when requested, a system flags menu 304, a user flags menu 306 and a test suite flags menu 308. These menus are shown in FIGS. 3A, 3B, 3C and 3D, respectively.
- the flag interface 118 main menu 302 comprises: a user mode dialog box 310 for enabling the user 113 to change a user mode system flag; and, an abort function 312, pause function 314, and a reset function 316 for enabling the user 113 to change abort, pause, or reset system flags.
- the flag interface main menu 302 further comprises a show system flags button 318, a show test suites button 320 and a show user flags button 322 for enabling the user 113 to have the system flags menu 304, the show test suite flags menu 308 and the user flags menu 306 displayed.
- the system flags window 304 of FIG. 3B comprises a report -- printer dialog box and slide bar 324, a bypass -- test -- level dialog box and slide bar 326, a pause -- on -- fail dialog box and slide bar 328, and a report file dialog box 330.
- the user 113 may change the value of a particular system flag by clicking on the associated dialog box and either entering a value in the dialog box or clicking on the slide bar to increase, decrease, or toggle its value.
- the system flags window 304 further comprises a slide bar 332 for scrolling to see additional system flags.
- a preferred embodiment of the present invention would have the following system flags (and possibly others):
- the prodshell 110 operates under several user modes:
- This flag indicates the standard production mode, which has minimal capabilities. The operator only has access to abort, pause, and reset buttons 312, 314 and 316.
- This flag option represents the next level of capability allowing calibration and other similar functions.
- a password is required to go up in user mode capability.
- abort This flag indicates that the abort button 312 was pushed (i.e., that the user 113 clicked on it).
- the current test running will stop at the next logical place in the testflow, and control of flow will return to the top level interface.
- pause This flag indicates the pause button 314 was pushed.
- the current testflow being executed will be completed for the current IC device 116 and a pause menu will be displayed.
- the contents of the pause menu varies depending on whether the IC device 116 is a wafer or a package. In either case, a user -- func button provides access to a user -- func test suite defined in
- debug -- level As the value of the debug -- level flag increases, more detailed general prodshell 110 execution information is provided.
- pause -- on -- fail This flag will allow a test to run until a failure occurs, and then the paused state is entered.
- report -- file This flag indicates whether reports are to be sent to the report file 132.
- report -- printer This flag indicates whether reports are to be sent to the printer 134.
- report -- window This flag indicates whether reports are to be sent to a reporting window 138 of the display device 136.
- run -- all -- tests This flag will allow all defined tests in a test suite to run. If the flag is false, then the test suite will run only until the first test failure.
- test suites flag menu 308 When on, the test suites flag menu 308 will be displayed. This flag is seen on the flag interface 118
- stop -- on -- fail This flag will allow breaking in the middle of a test, and moving to the next test. When on, it could favorably affect test time.
- the user flags menu 306 comprises a dialog box 332 and a slide bar 334 for each user flag 336. As with the system flags menu 302, there is a slide bar 332 for causing the window to display additional user flags by scrolling the user flags menu 306.
- the user flags are defined in the configuration file 128, as is explained above in the section entitled "Configuration File”.
- the test suite flags menu 308 comprises a grid of check boxes 338, the columns of which are identified by flag names 340 and the rows of which are identified by test suite names 342.
- the test suite flags menu 308 further comprises a slide bar 344 for scrolling that menu.
- test suite flags for each test suite (and possibly others):
- ignore -- fail Allows ignoring a failure in this test suite.
- pause Allows pausing the system before running this test suite to access a tester interface 140 of the tester 126.
- pass -- value This flag causes a value, rather than a mere pass/fail indication, to be output.
- fail -- value Outputs values for failed pins instead of just pass/fail.
- fail -- per -- pin Output failed information on a per pin rather than a pin list basis.
- buttons and dialog boxes of FIGS. 3A, 3B and 3C illustrate not only the flag interface 118's menus, but also its structure. Such is the case for all other menus described in this document as well.
- FIG. 4 is a flowchart of the flag interface 118 menu in carrying out the step 210 of executing the flag interface 118.
- the flag interface 118 allocates space for the system flags in the shared memory 112.
- the flag interface 118 initializes the system flags to appropriate default values.
- the flag interface 118 initializes the user mode to "operator.”
- the flag interface 118 updates the flag interface 118 menus. The method of menu updating is described in detail in FIGS. 5A and 5B and the accompanying text.
- the flag interface 118 then waits for a response from the user 113, which it receives in the form of an X event.
- step 420 the flag interface 118 processes it.
- the step 420 is explained in greater detail in FIGS. 6A and 6B and the accompanying text.
- FIGS. 5A and 5B show a flowchart of the method of a flag menus update widget in carrying out the step 416 of updating the flag interface 118 menus.
- the flag window update widget displays the abort button 312, the pause button 314 and the reset button 316, along with their associated values. It determines their values by examining the shared memory 112. Note that these values are initially set to false.
- the flag menus update widget displays the user mode dialog box 310 with the current user mode indicated therein (initially operator). It determines this value from the user -- mode flag in the shared memory 112.
- the flag menus update widget determines whether the requested user mode is "operator”. If so, the flag window update widget has finished, and control of flow returns to the step 418. (See step 516.)
- the flag menus update widget operates as follows. In a step 518, it displays the show system flags check box 318 and an indication of whether it is on or off. If the value is on, then (according to a step 520) the flag menus update widget carries out a step 522.
- the flag menus update widget invokes the system flags widget to display the system flags menu 304.
- the system flags widget determines the flag values to display in the window by consulting the shared memory 112.
- the flag menus update widget determines (in a step 524 of FIG. 5B) whether there are any test suite flags. If so, then in a step 524 it displays the show test suites check box 320 and its value (determined from the show -- suite flag in the shared memory 112). If the flag is on (see step 526), then in a step 528 a test suites widget displays the test suites menu 308. The test suites widget does so by examining the shared memory 112 to determine which test suite flags are defined and to determine the values associated with the test suite flags.
- the flag menus update widget determines whether the user mode is "engineer". If so, then the flag menus update widget operates as follows. In a step 532, it displays the show user flags check box and its value (determined from the show -- user flag in the shared memory 112). If that value is on (see step 534), then in a step 536 a user flags widget displays the user flags menu 306. The user flags widget determines the user flags and their values by examining the shared memory 112. Next, or after a negative determination any of in the steps 522, 530 or 534, control of flow returns to the flag interface 118 widget at the step 418.
- FIGS. 6A and 6B show a flowchart of the method of the flag interface 118 widget in carrying out the step 420 (processing an X event).
- the flag interface 118 widget determines whether the X event was a mouse click on the abort button 312. If so, then in a step 612, an abort widget toggles the abort flag in the shared memory 112.
- the flag interface 118 widget determines whether the X event was a click on the pause button 314. If so, then in a step 618, a pause widget toggles the value of the pause flag in the shared memory 112.
- the flag interface 118 widget determines whether the X event was a click on the reset button 316. If so, then a reset widget toggles the value of the reset flag in the shared memory 112.
- the flag interface 118 widget determines whether the X event was a click on the show system flags check box 318. If so, then a show system flags widget toggles the value associated with the show system flags check box 318.
- the flag interface 118 widget determines whether the X event was a click on the show test suites check box 320. If so, then in a step 630, a show test suites widget toggles the show -- suite flag in the shared memory 112.
- the flag interface 118 widget determines whether the X event was a click on the show user flags check box 320. If so, then in the step 634, a show user flags widget toggles the value of the show -- user flag in the shared memory 112.
- the flag interface 118 widget determines whether the X event was a click on the user mode dialog box 310. If so, then in a step 638, a user mode widget attempts to change the user mode. The operation of the user mode widget is described in detail below and is shown in FIG. 7.
- the flag interface 118 widget determines whether the X event was a click on the dialog box 332 or a click on a check box in the grid of check boxes 338. If so, then in a step 642, the value of the associated flag in shared memory is overwritten with the value in the dialog box.
- the flag interface 118 window determines whether the X event was a click on the slide bar associated with a flag. If so, then in step 646, the flag interface 118 executes the widget associated with the flag to increment, decrement or toggle the value in the shared memory 112.
- the flag interface 118 widget need only update the flag interface 118 windows.
- control of flow returns to the flag interface 118 widget at the step 416.
- FIG. 7 is a flow chart which shows the method of the user mode widget in carrying out the step 638 of FIG. 6B.
- the user mode widget receives the requested user mode from the user mode dialog box 310.
- the user mode widget determines whether the value associated with user mode received is greater than the current user mode. (The value of "operator” is 0; the value of "technician” is 1; and the value of "engineer”is 2.) If so, then the user mode widget operates as follows.
- the user mode widget receives a password from the user 113. In a step 716, it determines whether the password is correct. That is, it determines whether the text entered matches the password authorized for the user mode requested. If not, then in a step 718, the user mode widget signals an error, and control of flow returns to the flag interface 118 widget at the step 416.
- the user mode widget (in a step 720) sets the user -- mode flag to the value corresponding to the requested user mode. Control of flow then returns to the flag interface 118 widget at the step 416.
- the prodshell 110 executes the top level interface to query the user 113 for information needed to test the IC device 116 (see the step 212).
- the top level interface presents a top level menu 800 as shown in FIG. 8.
- the top level menu 800 comprises a quit button 810, a help button 812, a clear button 814, a recall button 816 and a select button 818.
- the buttons perform the following functions.
- the quit button 810 terminates the top level interface.
- the help button 812 provides on-line help capability.
- the clear button 814 clears the entries in the dialog boxes and check boxes of the top level menu 800.
- the recall button 816 recalls the last valid entry for a lot number, device type, device suffix, and operator ID (each of which is described below).
- the select button 818 verifies the correctness and completeness of all data entered on the top level menu 800 and writes the data to the shared memory 112. The functions of the buttons are described in greater detail in FIG. 9 and the accompanying text.
- the top level menu 800 further comprises a lot number dialog box 820, a device type dialog box 822, a device suffix box 823, an operator ID dialog box 824 and a valid device types box 826.
- the lot number is a site-specific identifier for a lot (i.e., a group) of IC devices to be tested.
- the top level interface has an environment variable which enables the user 113 to specify a format for the lot number.
- the device type is the type of the IC device 116.
- the device suffix specifies the configuration file 128 to be used in testing the IC device 116.
- the top level menu 800 further comprises test group check boxes 827, temperature boxes 833 and application check boxes 837.
- the test group check boxes 827 enable the user 113 to specify the type of test to be performed by selecting the production check box 828, the QA check box 830, or the engineering check box 832.
- the temperature boxes 833 enable the user 113 to specify the temperature at which the part will be tested by either selecting a room temperature check box 834 or an at temperature check box 836. If the user 113 selects the latter, he or she would then enter the desired temperature (e.g., in degrees Celsius) in a temperature dialog box 838.
- the user 113 specifies whether the IC device 116 is a die on a wafer or a package part, and whether the tests will be carried out manually. Specifically, the user 113 selects a wafer autoprobe check box 838, a wafer manual check box 840, a package handler 122 check box 842, or a package manual check box 844.
- FIG. 9 shows a high level flow chart of the method of the top level interface.
- the top level interface retrieves joint and independent recall buffers from a file.
- the joint recall buffer is a circular buffer which stores the last ten valid entries selected for the lot number, device type, device suffix and operator ID.
- Each independent recall buffer is a circular buffer which stores the last ten valid entries for either the lot number, the device type, the device suffix or the operator ID.
- the recall buffers Upon termination of the top level interface, the recall buffers will be written to a file. Accordingly, the recall buffers "remember" entries from previous sessions of the top level interface.
- the top level interface displays the top level menu 800.
- the top level interface then waits for a response from the user 113 in the form of an X event.
- the top level interface receives the X event in a step 912, and processes it in a step 914. After the step 914, control of flow returns to the step 912 to process additional X events.
- FIGS. 10A and 10B show a flow chart which illustrates the method of the top level interface in carrying out the step 914.
- the top level interface determines whether the X event was a mouse click on the recall button 816. If so, then in a step 1016, a recall widget displays the last valid entry for the lot number, device number, device suffix and operator ID in the corresponding dialog boxes. It determines the entries from the joint recall buffer.
- the top level interface determines whether the X event is a mouse click on the select button 818. If so, then in a step 1020 a select widget selects the data on the top level interface menu 800.
- FIG. 12 shows a flow chart of the detailed method by which the select widget carries out the step 1020.
- the top level interface determines whether the X event was a mouse click on the help button 812. If so, then in a step 1024, the help widget displays a context-sensitive help message.
- step 1028 the top level interface determines whether the X event is a mouse click on the quit button. If so, then in a step 1030 a quit widget writes the independent recall buffers to a file so that their contents are "remembered” between sessions of the top level interface. The quit widget then terminates the top level interface and returns a "quit" status to the prodshell 110 at the step 214.
- a prev widget retrieves the previous entry from the individual recall buffer associated with the active dialog box.
- a next widget retrieves the next entry from the independent buffer associated with the active dialog box. The operation of the next widget is similar to the prev widget, except that the next widget steps forward through the appropriate individual recall buffer.
- the top level interface determines whether the X event was a request to validate a lot number. That is, it determines whether the X event was either a press of the return key after clicking on the lot number dialog box 2432, or a message from the select widget requesting lot number validation. If so, then in a step 1048, a lot number widget validates the lot number in the dialog box. The method by which the lot number widget carries out the step 1048 is described in greater detail below with reference to FIG. 12.
- the top level interface determines whether the X event was a request to validate a device type. That is, it determines whether the X event was (1) a press of the return key after clicking on the device type dialog box or (2) a message from the select widget requesting a device type validation. If the X event was either (1) or (2) then in a step 1052, the base device type widget determines whether the data in the device type window is the name of the directory path stored in the environment variable "$DSH -- DUT -- PATH". If not, then in a step 1056 the device type widget indicates that the device type entered is invalid.
- the top level interface determines whether the X event was a request to validate a device suffix. In other words, it determines whether the X event was: (1) a press of the return key after clicking on the device suffix window or (2) a device suffix verification request from the select widget. If the X event was either (1) or (2), then in a step 1058, a device suffix widget validates the device suffix. The method by which the device suffix widget carries out the step 1058 is described in FIG. 12 and the accompanying text.
- an appropriate widget processes the event in a conventional manner.
- control of flow returns to the top level interface at the step 912 of FIG. 9.
- FIG. 11 is a flow chart which illustrates the method of the select widget in carrying out the step 1020 of FIG. 10A.
- the select widget invokes the lot number widget to validate the lot number. Lot number validation is described in FIG. 12 and the accompanying text.
- the select widget invokes the device type widget to validate the device type. Device type validation is described in FIG. 13 and the accompanying text.
- the select widget invokes the device suffix widget to validate the device suffix.
- Device suffix validation is described in FIG. 14 and the accompanying text.
- the select widget writes the joint and independent recall buffers to a file so that the buffers can be retrieved the next time the top level interface is invoked.
- the select widget writes the data entered on the top level interface menu 800 to the shared memory 112, where the prodtest 120 may later access it.
- the select widget then terminates the top level interface and returns a ⁇ select ⁇ status to the prodshell 110 (at the step 214 of FIG. 2).
- FIG. 12 shows a flow chart which illustrates the method of the lot number widget in performing validation.
- the lot number widget determines whether a lot number format is specified in an environment variable. If not, no further validation is performed. Otherwise, lot number validation proceeds as follows.
- the lot number widget determines whether the lot number entered on the top level interface menu conforms with the specified format. If not, then in a step 1213 an error message is generated. Otherwise, lot number validation proceeds as follows.
- the lot number widget determines whether an indication of the device type is embedded in the specified lot number format. If not, no further validation is possible. Otherwise, the lot number validation proceeds as follows.
- the lot number widget determines whether a device type has been entered on the top level menu 800 which does not match the device type embedded in the lot number format. If so, the lot number widget carries out the step 1213 (explained above). Otherwise, in a step 1218 the lot number widget displays the embedded device type in the device type dialog box 822. After either of the steps 1213 or 1218, or a negative determination in the step 1214, control of flow returns to the calling routine.
- FIG. 13 illustrates the method by which the device type widget performs validation.
- the device type widget determines whether the device type entered on the top level interface menu is a subdirectory in the directory stored in the environment variable called "$DSH -- DUT -- PATH". This directory must contain subdirectories for all valid device types. Accordingly, if there is no such subdirectory, then in a step 1312 the device type widget signals an error and lists all valid devices. Control of flow then returns to the widget which requested the device type validation.
- the device type widget displays the configuration files 128 (and any descriptions specified for them) for the IC device 116 in the valid device types dialog box 826.
- the configuration files 128 are listed in the device type subdirectory. Control of flow then returns to the widget which requested the device type validation.
- FIG. 14 shows a flow chart of the method of the device suffix widget in validating a device suffix.
- the device suffix widget determines whether the device suffix in the device suffix dialog box 823 is in a subdirectory called "$DSH -- DUT -- PATH/DEV -- TYPE/shell 110", where $DSH -- DUT -- PATH is an environment variable containing a directory path and DEV -- TYPE is the name of the device directory. If not, then in a step 1412 the device suffix widget signals an error. Otherwise, it operates as follows.
- the device suffix widget determines whether the configuration file 128 identified by the device suffix entered indicates a temperature. If so, then it continues as follows.
- step 1416 it determines whether the user mode is "operator.” If so, then in a step 1418 it replaces temperature boxes 833 with the indicated temperature. Otherwise, in a step 1420 the device suffix widget displays the indicated temperature as the default temperature.
- the device suffix widget proceeds as follows. In the step 1422, it determines whether the configuration file 128 indicates an application. If so, and if the user mode was found to be "operator" (see steps 1416 and 14324) then the device suffix widget replaces the application check boxes 837 with the indicated application. If the user mode is not "operator", then in a step 1428, it displays the indicated application as the default application. Specifically, it displays a check in the check box corresponding to the indicated application.
- control of flow returns to the widget which requested the device suffix validation.
- the prodshell 110 invokes the prodtest 120.
- the prodshell 110 could do so, for example, with the "fork" system call of the unix operating system. Accordingly, once the prodtest 120 terminates, control of flow returns to the prodshell 110.
- FIG. 1 shows the structure of the prodtest 120.
- the prodtest comprises a parser 142, a prodconf 144, a prober controller 146, a prober library 148, a handler controller 150, a handler library 152, a package controller 154 and a reporting module 156.
- the parser analyzes data in the configuration file 128 and places them in the prodconf 144.
- the prodconf 144 comprises, among other structures, a testflow structure 158 and a binning structure 160.
- the testflow structure essentially comprises a list of nodes representative of the testflow statements in the configuration file, and execution modules for carrying out the nodes.
- the testflow structure 158 is described in greater detail below in FIG. 25 and the accompanying text.
- the binning structure 160 comprises a list of binning rules, an otherwise clause, a list of good major bins, a list of reprobe major bins, a mapping of logical bins to physical bins, and a mapping of logical bins to colors.
- the binning structure 160 is described in greater detail below in FIG. 31 and the accompanying text.
- the prober controller 146 essentially ensures that the prober is properly positioned on the wafer IC device 116 for the next test to be executed. If the application is "wafer manual”, then it does so by prompting the user to position the prober. If the application is "wafer autoprobe”, then it does so by commanding the wafer prober 124 with routines in the prober library 148.
- the handler controller 150 essentially positions the package handler 122 to prepare the next package part IC device 116 for testing. It does this by commanding the package handier 122 with routines in the handler library 152.
- the handler controller is used when the application is "package handler".
- the package controller 154 prompts the user 113 to place the next package part IC device 116 on the package handler 122 for testing.
- the package controller 154 is used when the application is "package manual”.
- the reporting module 156 manages the reporting of results determined by the execution of the testflow structure 158 and the binning structure 160.
- FIG. 15 describes the high level method of the prodtest 120.
- the prodtest 120 starts the tester interface 140 to facilitate communications with the tester 126.
- the prodtest 120 executes the parser 142 to initialize the prodconf 144 with data from the configuration file 128.
- the parser 142 also creates test suite flags and may create user flags and change the value of system flags.
- the prodtest 120 notifies the flag interface 118 that flag values have been modified.
- the flag interface 118 responds by updating the flag interface 118 windows in step 416 of FIG. 4.
- the prodtest 120 downloads to the wafer prober 124 any wafer download file specified in the configuration file 128.
- the prodtest 120 downloads data to the tester 126. Specifically, the calibration file as well as any pin attribute and pin configuration files 128 specified in the configuration file 128. It also downloads chip specific information from the configuration file 128, including pin configurations, level settings, timing settings and vectors.
- the prodtest 120 examines the diceconf structure to determine whether the application is "wafer autoprobe" or "wafer manual”. If it is either type, then in a step 1518 the prodtest 120 executes the prober controller 146.
- the structure and method of the prober controller 146 is described below in the section entitled, "wafer prober controller”.
- the prodtest 120 determines whether the application specified was "package handler" 122. If so, then in a step 1526 the prodtest 120 executes the handler controller 150 of FIG. 17A.
- the structure and method of the handler controller 150 is described below in the subsection entitled "Handler Controller”.
- the prodtest 120 executes a package controller 154.
- the structure and method of the package controller 154 are described below in the subsection entitled, "Package Controller”.
- control of flow After carrying out any of the steps 1618, 1626 or 1628, control of flow returns to the prodshell 110 at the step 210.
- FIG. 16 is a block diagram of the structure of the prober controller 146.
- the prober controller 146 comprises a wafer entry interface 1616, an autotest module 1618, a manual test module 1620, and a user -- func module 1624.
- the wafer entry interface 1616 presents a graphical representation of wafer cassettes and accepts manual, file-based or wafer reader input of wafer numbers. It allows manipulation such as insertion, deletion and clearing of the wafer numbers. It is described below in greater detail in the section entitled, "Wafer entry interface".
- the user -- func module 1624 executes the user -- func test suite (if any) defined in the configuration file 128.
- FIG. 18 is a flow chart which illustrates the method of operation the prober controller 146.
- the prober controller 146 executes the wafer entry interface 1616 to assign numbers to the wafers to be tested.
- the method of operation of the wafer entry interface 1616 is described below in the subsection entitled, "Wafer Entry Interface”.
- a pre-test menu is displayed. If the application is "wafer autoprobe", then the pre-test menu presents a quit button, a help button and a select button. If the user -- func test suite is defined in the configuration file 128, then the pre-test menu further comprises a user -- func button.
- the menu further comprises a tester interface button for accessing commands of the tester 126.
- the prober controller 146 then waits for an X event (i.e., for the user 113 to press one of the buttons).
- the pre-test menu instructs the user to load the first wafer onto the wafer prober 124 and to press the select button when ready.
- the prober controller 146 determines whether the X event was a click on the user -- func button. If so, then in a step 1816, the user -- func module 1624 executes the user -- func test suite.
- the prober controller 146 determines whether the user 113 clicked on the select button. If not, then in a step 1820 it executes the widget associated with the button pressed. Thus, if the user 113 pressed the quit button, then the prober controller 146 terminates, and control of flow returns to the prodshell 110 at the step 210 of FIG. 2. If the user 113 pressed the help button, then it displays a context-sensitive help screen. If the tester 126 interface button was pressed, then a tester interface menu is displayed to enable the user to access the tester interface 140. After either of the steps 1816 or 1820, control of flow of the prober controller 146 returns to the step 1814 to receive additional commands from the user 113.
- the prober controller 146 executes the wafer map display in a step 1822.
- the operation of the wafer map display is described in greater detail below in the section entitled, "Wafer Map Display".
- the prober controller 146 determines whether there are additional wafers on the list of wafers entered by the user 113 which have not yet been tested. Once all wafers are tested, the prober controller 146 invokes the reporting module in step 1830 to summarize the test results and report them to the reporting window 138, the printer 134 and/or the report file 132 (depending on the system flag settings). Control of flow then returns to the prodshell 110 at the step 210.
- the wafer prober 124 controller gets the next wafer. If the application is wafer autoprobe, then it does so by issuing an appropriate command (supported by the wafer prober 124 library) to the wafer prober 124. If the application is wafer manual, on the other hand, then the wafer prober 124 controller 146 prompts the user 113 to place the next wafer on the wafer prober 124.
- the wafer prober 124 controller determines whether there are additional die on the current wafer which the user 113 has indicated should be tested. If all indicated dies have been tested, then control of flow of the wafer prober 124 controller returns to the step 1828 (explained above). Otherwise, the wafer prober 124 controller proceeds as follows.
- the prober controller 146 gets the next die to be tested. If the application is "wafer autoprobe", then it does so by issuing an appropriate command (supported by the wafer prober 124 library) to the wafer prober 124. Otherwise, it prompts the user 113 to enter the coordinates of the last die tested and advance the wafer prober 124 to the next die to be tested.
- the wafer prober 124 controller executes the prodconf 144 to execute the tests specified in the testflow structure 158 and the binning specified in the binning structure 160.
- the testflow structure 158 is described in greater detail below in the section entitled, "Testflow”.
- the binning structure 160 is described in greater detail below in the section entitled, "Binning”.
- the wafer prober 124 controller determines whether the value of the pause flag in the shared memory 112 indicates that the user 113 has requested a pause. If not, then control of flow returns to the step 1834. Otherwise, in a step 1848, the pause module 1622 of the wafer prober 124 controller processes the pause request. The method by which it does so is described below.
- FIG. 19 shows a flow chart of the method of the pause module in processing a pause.
- the pause module displays a pause menu.
- the pause menu contains quit, help, user -- func (if defined), clean probes, retest die, retest wafer, skip wafer, tester 126 software (if the user mode is "engineer"), and select buttons.
- the pause module then waits for a response from the user 113 (in the form of an X event).
- the pause module determines whether the X event received was a click on the user -- func button. If so, in a step 1914, it executes the user -- func test suite.
- the pause module determines whether the X event was a click on any of the buttons which request additional testing. If so, then in a step 1918, the pause module (using the routines in the prober library 148) positions the wafer prober 124 as follows. If the user 113 pressed the retest die button, then the pause module leaves the wafer prober 124 where it is so that the next test will be performed on the same IC device 116 as the previous test. If the user 113 pressed the retest wafer button, then the pause module issues a command (supported by the prober library 148) to the wafer prober 124 to return to the first die on the wafer.
- the pause module prompts the user 113 to load the next wafer and then advances to the first die of the next wafer. If the user 113 pressed the select button, then the pause module 1622 commands the prober to advance to the next die.
- step 1920 the pause module determines whether the X event was a click on the quit button. If not, then in a step 1922, it executes the widget associated with the button pressed. After any of the steps 1914, 1918 or 1922, control of flow returns to the wafer prober 124 controller at the step 1834.
- control of flow returns to the wafer prober 124 controller at the step 1830 to generate the testing and binning summary.
- FIGS. 23A, 23B and 23C show a flow chart which illustrates the method of, the wafer entry interface 1716.
- the wafer entry interface 1716 is called by the prober controller 146 in the step 1810 of FIG. 18.
- the wafer entry interface 1716 displays a wafer entry menu 2400, which is shown in FIG. 24.
- the wafer entry menu 2400 comprises a quit button 2410, a help button 2412, a read list button 2414, a save cassette button 2416, a flip list button 2418, an edit list button 2420, a move button 2422, a select button 2424, and a verify wafer checksum box 2426.
- the wafer entry menu 2400 further comprises an active cassette dialog box 2428 and three inactive cassette dialog boxes 2430.
- Each cassette dialog box 2430 comprises a lot number dialog box 2432 and a wafer number dialog box 2434.
- Wafers will be tested if they are highlighted.
- An unhighlighted wafer means the wafer is physically present in the cassette but is not to be tested (it will be skipped).
- the user 113 can toggle highlighting and unhighlighting of a wafer by clicking on it once with the mouse.
- the user 113 can remove a wafer from the list by double clicking on it with the mouse. This copies a wafer to the wafer text entry box. (See the edit list button described below). The wafer number can then be edited.
- the buttons of the wafer entry menu 2400 operate only on the active cassette 2428.
- the active cassette 2428 is changed by clicking on the lot number dialog box 2432 with the left mouse button, typing in a lot number (which will be validated) and pressing return. Alteratively, it can be changed by clicking on a wafer number in one of the cassette dialog boxes 2434.
- the wafer entry interface 1616 waits for a response by the user 113 (in the form of an X event). Once it receives the X event in the step 2312, the wafer entry interface 1616 determines whether, in step 2314, the X event was a click on the read list button 2414. If so, a read list widget associated with the read list button 2414 reads a list of wafers from a file into the wafer number dialog box 2434 of the active cassette 2428. Specifically, in a step 2316 the read list widget gets the wafer numbers from a file called "war -- list". The war -- list file could be generated by a wafer laser number reader.
- the read list widget displays the wafer numbers in the wafer number dialog box 2434 of the active cassette 2428. Control of flow then returns to the step 2312 to await the user's next request.
- the wafer entry interface 1716 determines whether the X event was a click on the save cassette button 2416. If so, then in a step 2322, a save cassette widget associated with the save cassette button 2416 validates the wafer numbers in the active cassette. Validation involves determining whether there are duplicate wafer numbers in a single lot and, if the verify wafer checksum check box 2426 is checked, then determining whether each wafer number complies with the wafer numbering standard used at the site. Then, in a step 2324 the save cassette widget writes the wafer numbers to a file, the name of which is indicated by the lot number of the cassette. If the user 113 has indicated that any of the wafer numbers are not to be tested, then the widget precedes these numbers in the file with the "#".
- the wafer entry interface 1716 determines whether the X event was a click on the flip list button 2418. If so, then in a step 2328, a flip list widget inverts the wafer numbers on the active cassette dialog box. This is useful if the wafer prober 124 reverses the wafer order in cassettes as it tests the wafers.
- the wafer entry interface 1616 determines whether the X event was a click on the edit list button 2420. If so, then in a step 2332, an edit list widget displays a text edit window for adding wafer numbers to the active cassette.
- the user 113 can type wafer numbers into the window one at a time. The wafer numbers are verified and then appended to the wafer number dialog box 2434 of the active cassette 2428. Alternatively, the user 113 can insert a wafer number at a specified numeric position of the wafer number dialog box 2434 by typing "@position" after the wafer number.
- the wafer entry interface 1616 determines whether the X event was a click on a stop edit button. (The stop edit button replaces the edit list button 2420 when the text edit window is displayed.) If so, then in a step 2336 the wafer entry interface 1616 removes the text edit window from the wafer entry interface 1616 menu 2400.
- the wafer entry interface 1616 determines whether the X event was a click on a make sequence button. (The make sequence button is displayed by clicking on the more button 2422.) If so, then in a step 2340 it lists consecutive wafer numbers in the wafer number dialog box 2434. If the lot number of the active cassette dialog box 2428 is the same as that of the preceding inactive cassette dialog box 2430, the numbering continues where the last cassette left off. Otherwise, the numbering starts at 1.
- the wafer entry interface 1616 determines whether the X event was a click on the quit button 2410, indicating a request to leave the wafer entry interface 1616 without entering the data. Any previously entered data will be ignored. If so, then in a step 2334, it sets a variable in the shared memory 112 for the number of lots to 0. In a step 2346, it sets variables in the shared memory 112 for each lot number to null. Control of flow then returns to the prober controller 146 at the step 1812 of FIG. 18A.
- step 2348 the wafer entry interface 1616 determines whether the X event was a click on the select button 2424. If not, then in a step 2350 the wafer entry interface 1616 executes whatever request was indicated by the X event. After execution of any of the steps 2350, 2318, 2324, 2328, 2332, 2336 or 2340, control of flow returns to the step 2312 of FIG. 23A to wait for the next X event.
- a select widget associated with the select button 2424 validates the lot numbers. Specifically, it ensures that each lot number conforms to a pre-specified lot number format.
- the lot number format is specified in an environment variable read by the wafer entry interface 1716.
- the wafer entry interface 1716 writes each different lot number to a lot number variable in the shared memory 112. If the wafer numbers of a single cassette are entered in more than one wafer number dialog box 2434, then there may be duplicate lot numbers. In a step 2356, it writes the number of different lot numbers to the lots variable in the shared memory 112.
- the wafer entry interface 1616 validates the wafer numbers. Wafer number validation is described above in this section.
- a step 2360 it writes the wafer numbers in each wafer number dialog box 2434 to a file identified by the lot number of the window. If wafer numbers from multiple wafer number menus 2434 are written to a single file, then a delimiter is placed between each set of wafer numbers. Also, as described above, any unhighlighted wafers are preceded by a "#". Control of flow then returns to the wafer prober 124 controller at the step 1812.
- the wafer map display 164 is used to display the test results of each die on a wafer as it is tested.
- FIG. 28 shows a wafer map 2800 generated by the wafer map display 164.
- the wafer map 2800 comprises a wafer template 2810 of die cells representative of dies on a wafer, x coordinates 2814 and y coordinates 2816 to facilitate identification of individual dies, a lot number 2818, a wafer number 2820 and a wafer test summary 2822.
- Each die cell 2812 has a major bin identifier 2824, a minor bin identifier 2826 and a fingerprint 2828 as well as a color (not shown).
- the fingerprint 2828 is in the form first fail/total fail/total run, where first fail is the number of the first test failed by the die, total fail is the total number of tests failed by the die and total run is the total number of tests executed on the die.
- the purpose of the fingerprint 2828 is to facilitate easy recognition of repeating patterns of defects. Defects on IC devices are generally caused by the falling of dust particles during fabrication and are therefore generally randomly distributed. Accordingly, a repeating pattern of defects indicates either: (1) a repeating defect in the silicon, or (2) an anomaly in the test setup or in how the test is written.
- FIG. 29 is a block diagram of the structure of the wafer map display 164.
- the wafer map display 164 comprises a template constructor 2910, a cell updater 2912 and a summary generator.
- the cell updater 2912 comprises a footprint generator 2916.
- FIG. 20 is a flowchart which illustrates the method of the wafer map display 164.
- the template constructor 2910 determines the dimensions of the current wafer and of each die on the wafer. It extracts the data from the prober download file specified in the configuration file 128.
- the template constructor 2910 uses the data to create the wafer template 2810 in a step 2012. In a step 2014, it displays the template on the display device 136.
- the die cells 2812 are initially blank and black.
- the wafer map display 164 then waits for a message from the reporting module 156. Once the wafer map display 164 receives such a message in a step 2016, it determines in a step 2017 whether the message is a request to update a die cell 2912. If so, then the cell updater 2912 carries out steps 2018 through 2024.
- the cell updater 2912 colors the die cell the color mapped to by the major bin indicated by the test result. Mapping of major bins to colors is specified in the binning section of the configuration file 128.
- the cell updater 2912 writes the two identifying characters of the die's major bin into the die cell 2812. Then, in the step 2022, it writes the first five characters of the die's minor bin into the die cell 2812. The characters associated with the major bin and the minor bin are also specified in the binning section of the configuration file 128.
- the fingerprint generator 2916 determines the number of first tests failed, the total number of tests failed and the total number of tests executed on the die; the fingerprint generator then writes the fingerprint into the die cell. Control of flow then returns to the step 2016 to wait for additional messages from the reporting module 156.
- the wafer map display 164 summarizes the results of the tests performed so as to generate the wafer summary 2822. In the step 2026 it displays the wafer summary 2822 at the bottom of the wafer map 2800. Control of flow then returns to the reporting module 156.
- FIG. 17A shows a block diagram of the structure of the handler controller 150 executed in the step 1526 of FIG. 15.
- the handler controller 150 comprises a handler interface 1726 and the user -- func module 1724.
- FIGS. 21A and 21B show a flow chart which illustrates the method of operation of the handler controller 150.
- the handler interface 1726 displays a package handler menu having quit, help, user -- func, end lot, retest, show summary, show display and select buttons. It then waits to receive a response from the user 113 (in the form of an X event).
- the handler 122 controller determines whether it is a click on the user -- func button. If so, then in a step 2116 the user -- func module 1724 executes the user -- func test suite.
- the handler controller 150 determines whether the X event was a click on the show display button. If so, then in a step 2120 it sends a message to the reporting module 156 to execute the package display module 162. The reporting module 156 will then send an update message to the package display module 162 after each test is performed.
- the handler controller 150 determines whether the X event was a click on the quit button. If so, then in a step 2124 it invokes the reporting module 156 to generate a report summary. The reporting module 156 will then transmit the summary to the reporting window 138, the printer 134 and/or the report file 132 (whichever are specified by the system flags). Control of flow then returns to the prodshell 110 at the step 210.
- the handler controller 150 determines whether the X event was a click on the select button. If not, then in a step 2128 it executes the widget associated with the button pressed.
- the handler controller 150 determines whether there are additional untested packages in the tray currently in the package handler 122. If not, then control of flow returns to the step 2112. Otherwise, the handler controller 150 operates as follows.
- the handler interface 1726 prompts the user 113 to insert a tray of packages into the package handler 122 and press select. Once the user 113 does so, then in a step 2134 the handler controller 150 executes the prodconf 144. Execution of the prodconf 144 is described below in the section entitled "Prodconf”. Control of flow then returns to the step 2132 to process any additional packages.
- FIG. 17B shows a block diagram of the structure of the package controller 154 executed in the step 1626 of FIG. 16.
- the package controller 154 comprises a package interface 1728 and the user -- func module 1724.
- FIG. 22 shows a flow chart which illustrates the method of the package controller. Referring to FIG. 22, in a step 2210 the package interface 1728 displays an initial package menu having quit, help, user -- func, standard, tester control (if the user mode is engineer) and select buttons. The package controller 154 then waits to receive a response from the user 113 (in the form of an X event).
- the package controller determines whether it is a click on the user -- func button. If so, then in a step 2216 the user -- func module 1724 executes the user -- func test suite.
- the package controller determines whether the X event was a click on the quit button. If so, then in a step 2220 it invokes the reporting module 156 to generate a report summary. The reporting module 156 will then transmit the summary to the reporting window 138, the printer 134 and/or the report file 132 (whichever are specified by the system flags). Control of flow then returns to the prodshell 110 at the step 210.
- the package controller determines whether the X event was a click on the standard button. If so, then in a step 2224 the package interface 1728 prompts the user 113 to place a known good package (i.e., a standard package) in the tester 126. This enables the user 113 to verify the test setup. (Note that test results of the standard package are not included in the test summary.) After the first package is tested, the package interface 1728 will display a retest button and a summary button in addition to the buttons listed above. It will then prompt the user 113 to load the first package and press the select button.
- a known good package i.e., a standard package
- the package controller determines whether the X event was a click on the select button. If not, then in a step 2228 it executes the widget associated with the button pressed. Specifically, if the user 113 pressed the tester control button, it executes a widget to provide the user 113 with access to routines supported by the tester interface 140. If the user 113 pressed the help button, the package controller executes a widget to display a context-sensitive help message.
- the package interface 1728 prompts the user 113 to put the next package to be tested in the tester 126 and press the select button. Once the user 113 does so, then in a step 2232 the package controller executes the prodconf 144. Execution of the prodconf 144 is described below in the section entitled "Prodconf". Control of flow then returns to the step 2212 to process additional X events.
- the prober controller 146, the handler controller 150 and the package controller 154 execute the prodconf 144 on each IC device 116.
- the prodconf 144 comprises a testflow module 158 for processing the testflow description of the configuration file 128 and a binning module 160 for processing the binning description of the configuration file 128.
- FIG. 30 shows a flowchart which illustrates the method of the prodconf 144.
- the prodconf executes the testflow module to execute tests on the IC device 116 as specified in the testflow description.
- the testflow module is explained in greater detail below in the section entitled "Testflow”.
- the prodconf 144 executes the binning module 160 to perform the binning as specified in the binning description.
- the binning module is described in greater detail below in the section entitled "Binning". As is explained in that section, the binning description can specify that the IC device 116 be reprobed as a consequence of particular test results. Accordingly, in a step 3014, the binning module 160 determines whether the test results indicate that the IC device 116 should be reprobed. If so, then in a step 3016 the binning module 160 determines whether the IC device 116 has already been reprobed more than a specified maximum number of times and, if not, sets a reprobe flag. If the reprobe flag is set, then the prober controller 146, the handler controller 148 or the package controller 150 will cause the IC device 116 under test to be reprobed. (The maximum number of reprobes is specified by the user 113.).
- the prodconf executes the reporting module 156.
- the reporter module 156 transmits the results to the reporting window 138, the printer 134, and/or the report file 132. If the IC device 116 is a die on a wafer, then the reporting module further transmits the test results (as an update message) to the wafer map display 164. If the IC device 116 was a package part and the user 113 did not turn off the "show display" flag (see step 2118 of FIG. 21A), then the reporting module 156 transmits the results (as an update message) to the package display 162.
- the package display 162 Upon receiving the message, the package display 162 displays a package template representative of the package just tested. The package display 162 will color the package template green if the package was found to be a shippable part, and red otherwise. It will also display the two major bin characters and the first five minor bin characters for the major bin and minor bin determined by the binning module 160. Finally, it will display the fingerprint of the package. That is, it will write the number of the first test that the package failed, the total number of tests that the package failed, and the number of tests executed on the package.
- control of flow returns to the calling module (i.e., the prober controller 146, the handler controller 150 or the package controller 154).
- testflow list 2500 of the testflow 158 is a simple programming language used to specify and control the way in which test suites are applied to the IC device 116 under test.
- the testflow 158 is executed once for each IC device under test, whether the IC device 116 is a die on a wafer or a package part.
- the testflow description comprises at least one statement, where a statement is of one of the following forms, and text following "--" is a comment.
- a ⁇ real -- number> is any integer or real number, containing [0-9]and, for real numbers, the decimal point.
- FIG. 25 shows the structure of the testflow list 2500.
- the testflow list has a node for each type of statement in the testflow description.
- the nodes of the testflow are described as follows.
- a run node 2510 points to a test suite 2512 and comprises an execute module 2514 for executing the test suite 2512.
- a print node 2516 points to a variable 2518 and comprises an execute module 2520 for printing the variable 2518.
- An if node 2522 points to a condition 2524, an ifFlow node 2526, and an elseFlow node 2528.
- the if node 2522 comprises an execute module 2530 for (1) evaluating the condition 2524, (2) causing execution of the ifFlow node 2526 if the condition is true, and (3) causing the execution of the elseFlow node 2528 if that node is not null and the condition is false.
- a while node 2532 has a pointer to a condition 2534 and to a loopFlow node 2536.
- the while node comprises an execute module 2538 for evaluating the condition 2534 and, while the condition is true, causing the execution of the loopFlow node 2536.
- a repeat node 2540 has a pointer to a loopFlow 2542 and to a condition 2544.
- the repeat node 2540 comprises an execute module 2546 for causing the execution of the loopFlow node 2542 and evaluating the condition 2544 to determine if the execution of the loopFlow node 2542 is repeated.
- An assign node 2548 has a pointer to a right hand side 2550 and to a left hand side 2552.
- the assign node 2548 comprises an execute module 2554 for evaluating the right hand side (if it is an expression) and assigning the value of the right hand side 2550 to the left hand side 2552.
- a compound node 2554 has a pointer to a testflow sublist 2556 of the testflow list 2500, and comprises an execute module 2558.
- the testflow sublist 2556 comprises at least one flow node.
- the execute module 2558 causes the execution of all testflow nodes on the testflow sublist 2556.
- a stop node 2560 comprises an execute module 2562 for breaking out of a loop which is processing the testflow sublist 2500 (or the testflow sublist 2556).
- a null node 2564 comprises an execute module 2566 for returning control of flow to the node that called the null node. (The null statement does nothing.)
- FIGS. 26A, 26B and 26C show a flow chart of the method of the testflow module 158.
- the testflow module 158 determines whether there are additional Flow nodes to process. Once all Flow nodes have been processed, then in a step 2612 control of flow returns to the calling module. That is, it returns to the prober controller 146 at the step 1840, to the handler 122 controller 150 at the step 2136, or to the package controller 154 at the step 2234. Otherwise, the testflow module 158 proceeds as follows. In a step 2614, it retrieves the next node of the testflow list 2500. In a step 2616, it determines whether the flow node is the run node 2510. If so, then the execute module 2514 of the run node executes the associated test suite 2512.
- the testflow module 158 determines whether the flow node is the if node 2522 in a step 2620. If so, then in step 2622 the associated execute module 2530 evaluates the condition 2524. If the condition is true, then in a step 2628 the execute module 2530 causes the ifFlow 2526 to be executed. It does so by invoking the execute module of the appropriate node. For example, if the ifFlow node 2526 were a print node 2516, then the execute module 2520 would print the variable specified.
- step 2630 determines whether there is an elseFlow node 2528. If so, then in a step 2632 it causes the elseFlow node 2528 to be executed. After the step 2628 or 2632, control of flow returns to the step 2610 to process any additional flow nodes.
- testflow module 158 determines whether the flow node is the while node 2532. If so, then in a step 2636 the execute module 2538 determines whether the condition 2534 is true. If so, then in a step 2640 it executes the loop flow 2536. Control of flow then returns to the step 2636 to determine whether the condition 2534 is still true. Once the condition 2534 is found not to be true in the step 2638, control of flow returns to the step 2610.
- the testflow module 158 determines whether the flow node is the repeat node 2540. If so, then in a step 2644 the execute module 2546 causes the loop flow node 2542 to be executed. In a step 2646 the execute module 2546 evaluates the condition 2544. If the condition is true, then in a step 2648 control of flow returns to the step 2644 to again execute the loop flow node 2542. Otherwise, control of flow returns to the step 2610 of FIG. 26A.
- testflow module 158 determines whether the flow is the compound node 2554. If so, then in a step 2652 the execute module 2558 causes the execution of the testflow sublist 2556. It does so with a recursive call to the testFlow module 156. Control of flow then returns to the step 2610.
- the testflow module 158 determines whether the flow node was the assign node 2548. If so, then in a step 2656 the execute module 2554 determines whether the RHS node 2550 contains an expression. If so, then in a step 2658 the execute module 2554 evaluates the expression. If, on the other hand, the RHS node 2550 contains a simple value, or after the step 2658, then in a step 2660 the execute module 2554 assigns the value of the RHS node 2550 to the variable of the LHS node 2552. Control of flow then returns to the step 2610 of FIG. 26A.
- testflow module 158 determines whether the flow node is the "print" node 2516. If so, then in a step 2664 the execute module 2520 prints the value of the variable 2518. Control of flow then returns to the step 2610.
- the testflow module 158 determines whether the flow node is the "stop" node 2560. If so, the execute module 2562 causes control of flow to break out of the loop processing the nodes on the testflow list 2500. That is, it causes control of flow to go to the step 2612 of FIG. 26A.
- the binning module is executed to characterize the quality of the IC device 116 based on the test results. Operation of the binning module is specified in the binning description of the configuration file 128.
- Each binning rule in the binning description specifies a major bin and a minor bin.
- a major bin can be used to indicate a general type of failure, such as a short, a continuity failure, an AC failure, or a DC failure.
- Minor bins could be used to provide more information about a failure at a glance, but may only be meaningful to one familiar with the IC device 116 under tests. Several minor bins can map into one major bin.
- the binning module 160 processes the binning description essentially as follows. When an expression within a binning rule is true, the IC device 116 just tested is assigned the major bin and the minor bin contained in that binning rule. Binning rules are evaluated in the order in which they are listed. Binning rules following the first true rule are ignored. This allows for less complex binning equations, but also can yield different results if equations are reordered.
- the IC device 116 is binned according to the otherwise clause when no binning rule is true.
- the good keyword is used to define the list of major bins which are shippable parts.
- the reprobe keyword is used to define the list of major bins which should be reprobed if the initial test fails.
- the physical -- mapping keyword is used to define a mapping of logical bins to physical bins, for example, output bins on the package handler 122.
- the color -- mapping keyword is used to assign a color to a logical bin when the binning result is displayed by the package display 162 or the wafer display 164.
- FIG. 31 shows a block diagram of the structure of the binning module 160.
- the binning module 160 comprises a list of binning rules 3110, an otherwise clause 3114, major bin lists 3116 and a find -- true module 3118.
- Each binning rule 3112 of the binning rule list 3110 comprises an expression 3120, a major bin 3122 and a minor bin 3124.
- the otherwise clause 3114 also comprises the major bin 3122 and the minor bin 3124.
- the major bin lists 3116 comprise a good list 3126 containing the major bins following good keyword in the binning description, a reprobe list 3128 comprising the major bins following the reprobe keyword, a physical map 3130 comprising the logical bin/physical bin pairs following the physical -- mapping keyword, and a color map 3132 comprising the logical bin/color pairs following the color -- mapping keyword.
- the find -- true module 3118 traverses the binning rule list 3110 until it finds a binning rule 3112 whose expression 3120 is true.
- the structures and module of the binning module 160 are further described in FIGS. 27A and 27B.
- FIGS. 27A and 27B show a flow chart which illustrates the method of the binning module 160.
- the binning module determines whether there are additional binning rules 3112 on the binning list 3110. If so, then in a step 2712 it retrieves the next such rule (referred to as the current binning rule 3112).
- the find -- true module 3118 evaluates the expression 3120 of the current binning rule 3112. If the expression is false (see step 2716), then control of flow returns to the step 2710. Accordingly, the find -- true module 3118 will traverse the binning rule list 3112 until finding a binning rule 3112 whose expression 3120 is true or until there are no more binning rules 3112 on the binning list 3110.
- the find -- true module 3118 found a binning rule 3112 whose expression 3120 was true, then in a step 2718 the binning module 160 sets the major bin of the IC device 116 just tested to the major bin 3122 of that binning rule 3112. In a step 2720, it sets the minor bin of the IC device 116 to the minor bin 3124 of the binning rule 3112.
- the find -- true module 3118 found no binning rule 3112 whose expression 3120 was true, then in a step 2722 the binning module sets the major bin 3122 of the IC device 116 just tested to the major bin of the otherwise clause 314. It then sets the minor bin of the IC device 116 to the minor bin 3124 of the otherwise clause 314 in the step 2724.
- the binning module 160 determines whether the major bin of the IC device 116 is on the good list 3126. If so, then in a step 2728 it sets the quality of IC device 116 to good. Otherwise, in a step 2730 it sets the quality to bad.
- the binning module determines whether the major bin of the IC device 116 is on the reprobe list. If so, then in a step 2734 the binning module 160 indicates that the IC device 116 should be reprobed. Otherwise, in a step 2736, it indicates that the IC device 116 should not be reprobed.
- the binning module sets the physical bin of the IC device 116 to the physical bin in the physical map 3130 mapped to the major bin of the IC device 116.
- it sets the color of the IC device 116 to the color in the color map 3132 mapped to the major bin of the IC device 116. Control of flow then returns to the calling module (that is, the prober controller 146, the handler controller 150 or the package controller 154).
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Abstract
Description
__________________________________________________________________________ Init specification -- Test suite to execute when the diceconf is started Abort specification -- Test suite to execute when abort is pressed Pause specification -- Test suite to execute when pause is pressed Reset specification -- Test suite to execute when reset is pressed User.sub.-- func specification -- Test suite to execute when user.sub.-- func button is pressed; the test suite would commonly call the user code discussed above Exit specification -- Test suite to execute when the diceconf is __________________________________________________________________________ finished
______________________________________ if expression bin = "major.sub.-- bin" "minor.sub.-- bin"; . . otherwise bin = "major.sub.-- bin" "minor.sub.-- bin"; ______________________________________
__________________________________________________________________________ run(<test.sub.-- suite>); a run statement print(@<var.sub.-- name); a print statement if <expression> then <statement>; an if statement [else <statement>;] an else clause while <expression> do <statement>; a while statement repeat <statement>; until <expression> a repeat statement { <statement>; [<statement>;] } a compound statement @<var.sub.-- name> = <expression> an expression assignment statement @<var name> = "<string>" a string-assignment statement @<var.sub.-- name> = <string.sub.-- expression> a string expression assignment statement a null statement stop; a stop statement __________________________________________________________________________
__________________________________________________________________________ pass(<test.sub.-- suite>) 1 if<test suite> passed, 0 otherwise fail(<test.sub.-- suite>) 1 if <test suite> failed, 0 otherwise has.sub.-- run(<test.sub.-- suite>) 1 if <test suite> has run, 0 otherwise has.sub.-- not.sub.-- run(<test.sub.-- suite>) 1 if <test suite> has not run, 0 otherwise ( expression ) @<var.sub.-- name> <real.sub.-- number> "<string > " <string.sub.-- expression > __________________________________________________________________________ A<test suite>in the testflow description is a previously defined test suite name, and a<var.sub.-- name>is an alphanumeric label of a variable. A<string>is any sequence of ASCII characters. A <string.sub.-- expression>is a string expression with strings as operands and operators:
==
?=
______________________________________ Keyword Line: binning Entry line: <binning.sub.-- rule>; [...] otherwise bin = <major.sub.-- bin> <minor.sub.-- bin>; good = <major.sub.-- bin.sub.-- list>; reprobe = <major.sub.-- bin.sub.-- list>; physical.sub.-- mapping <number> = <major.sub.-- bin.sub.-- list>; [...] color.sub.-- mapping <color> = <major.sub.-- bin.sub.-- list>; [...] ______________________________________
__________________________________________________________________________ <binning.sub.-- rule> = if <expression> bin = <major.sub.-- bin> <minor.sub.-- bin> <expression > = a boolean expression with operators ">", ">=", "<", "<=", "==", "!=", "(",")", "and", "or", and "not". (Note that the quotes here are not literal and are only used for clarity.) and operands pass(<test.sub.-- suite>) fail(<test.sub.-- suite>) has.sub.-- run(<test.sub.-- suite>) has.sub.-- not.sub.-- run(<test.sub.-- suite>) ( expression ) @<var.sub.-- name> <real.sub.-- number> "<string >" <test.sub.-- suite> = previously defined test suite name <var.sub.-- name> = an alphanumeric label, with a letter as the first character. See the declarations section for a complete description of variables <string > = any sequence of ASCII characters <string.sub.-- expression > = a string expression with operators "==", "!", "+", and with strings as operands. <real.sub.-- number> = any integer real number, containing [0-9] and for real numbers, the decimal point. <major.sub.-- bin> = location or industry standard bin <minor.sub.-- bin> = user-defined bin for diagnostic purposes <major.sub.-- bin.sub.-- list> = comma separated list of one or more major bins <number> = an integer number <color> = an integer number (where 0 = black, 1 = white, 2 = red, 3 = yellow, 4 = green, 5 = cyan, 6 = blue, 7 = magenta), or the name of the color in lower case. __________________________________________________________________________
______________________________________ binning major minor ______________________________________ if fail(continuity) bin = "ZC" "continuity.sub.-- failure"; if fail(nominal) bin = "BZ" "non.sub.-- functional"; if fail(nominal2) bin = "BA" "almost.sub.-- good"; if pass(nominal2) bin = "AA" "good.sub.-- part"; otherwise bin = "XX" "oops"; good = "AA"; reprobe = "ZC"; physical.sub.-- mapping 1 = "ZC"; 2 = "BZ", "BA"; 3 = "AA"; 4 = "XX"; color.sub.-- mapping red = "ZC"; yellow = "BZ", "BA"; green = "AA"; black = "XX"; end ______________________________________
Claims (24)
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